Build Your Own Emergency Radiation Detector Electroscope

By Ed Perley

INTRODUCTION

An electroscope is a device that is used to demonstrate
properties of static electricty. Static electricity is a
phenomenom that takes many forms. It can be an electric shock you
can get after walking over a carpet, or it can be a lightning
bolt from the sky. The electroscope demonstrates the repulsive
force that is exerted between two nearby objects with the same electric
charge. This page tells how you can make your own electroscope
from materials commonly found in your house.

The design of this device was described in the Omaha World
Herald's "This Week Magazine" in the late 1950,s, a time when
the fear of nuclear war and the resulting nuclear
radiation was very real. It was billed as a simple device
for detecting dangerous levels of this radiation. But it is
also useful for demonstrating repulsive forces associated with
static electrity.

MATERIALS

Synthetic thread (nylon preferred).

Aluminum foil.

One quarter dollar or something with similar diameter.

A glass jar (Select one that is as wide as possible).

A metal jar or can lid to fit over the top.

A drill or punch to put holes through the jar lid.

A plastic comb and hair to generate static electricity.

PROCEDURE

Using the quarter, trace and cut out two circles of aluminum foil.

Stretch two 1 foot lengths of thread upon a flat surface.

Put a bend about 1/32 inch in from the edge of each circle.

Attach one circle to each thread in the middle by folding this
bend over the thread.

Drill a hole on opposite sides of the lid. The distance
between them should be about 1/2 inch less than the inside diameter
of the mouth of the jar.

Slip the ends of the threads through the holes and secure with
tape so that the foil circles are suspended as shown in the
illustration. Put the lid on the jar so that the circles hang
inside it. There should be plenty of clearance between the
circles and the walls of the jar. Cut off excess thread.

Remove the lid and line the inside of the jar with aluminum foil.
Cut the foil
so that there are two windows on each side of
the glass. They should be lined up so that you can easily see the
circles when they are hanging inside the jar.

Draw a simple scale on a small piece of paper with lines about
1/8 inches apart. Tape it horizontally under one of the windows so
that you can measure the distance between the two circles hanging inside.

CHARGING UP THE ELECTROSCOPE

Run a plastic comb through your hair and touch it to the
circles. After a moment of attraction they will repel each other.
The static electricity will hold them about an inch apart.

Carefully hang the circles in the jar, trying to keep them
from touching the aluminum foil liner. If necessary, a quick touch of
one of the circles with the inside wall will reduce the gap between them,
making this action easier.

HOW IT WORKS

Rubbing a comb in your hair puts a positive charge on the comb.
Touching the comb to the circles transfers some of the charge to
them. Because of their light weight, static electric repulsive forces
push them apart.

The foil lined jar serves as an electrostatic "bottle" that slows the
rate at which the charge leaks away. This loss of charge will happen
more rapidly in a location where there is nuclear radiation. Impacts
of beta rays, high energy negatively charged electrons, will cause the
circles to lose their positive charges. Therefore the gap between the
circles will close more rapidly.

DETECTING RADIATION

This device can be used to detect dangerous levels of beta radiation.
It will not detect other forms of nuclear radiation. Alpha
particles are positively charged, but they are too massive to
penetrate the glass. Gamma rays and neutrons can hit the circles,
but because they have no charge, they have no significant effect.

I recently discovered I still have the instructions for calculating
radiation levels using the electroscope. There will be a possibility of error
because I do not remember for sure the spacing between the line on the scale.
(I think it is 1/8 inch, but it could be 1/16 inch.)

Multiply the number of seconds for the leaves to go together from one pair
of scale lines to the next, by ten. The value you get is the number of hours
of exposure you can survive at the current radiation level. A time of 600 seconds
(10 minutes) indicates no significant radiation. Under normal conditions, it
should take between ten and thirty minutes for the leaves to move from one pair
of scale lines to the next.

You may have some potential low level radiation sources to test with
your electroscope. Color televisions, especially the oldest ones,
emit radiation, mostly from the top and sides. Smoke detectors,
may also give off some radiation. If you
have access to radioctive isotopes in a nuclear lab, you could
put it inside the jar for maximum effect. (Don't have anything
to do with nuclear isotopes unless you know what you are doing!)
I have never done any experiments like this. Please let me know
if one works for you. Forget about microwave ovens. Their radiation
is much different.

So, have fun experimenting with your electroscope. And, if there
ever is (heaven forbid) a nuclear holocaust or nuclear reactor meltdown,
you'll be ready.